JP4453234B2 - Glass substrate for hard disk and manufacturing method thereof - Google Patents

Description

【００５７】
比較例1
重心コアリング処理の代わりに従来のコアリング処理を、内周端面精密加工処理の代わりに従来の端面精密加工処理（内外）を、内周端面研磨加工処理の代わりに従来の端面研磨加工処理（内外）を行ったこと以外、実施例1と同様の方法に従って、中央孔を備えたハードディスク用ガラス基板を製造した。
従来のコアリング処理においては、ガラス基板の外周端部を切断してガラス基板の外径寸法および真円度を予備調整した後、該ガラス基板の中心を中心として中央孔を形成した。
従来の端面精密加工処理（内外）においては、中央孔の内周端面とともに外周端面を研削および面取りした。
従来の端面研磨加工処理（内外）においては、中央孔の内周端面とともに外周端面を研磨した。
【００５８】
実施例2
図1のフローチャートに基づいて中央孔を備えていない外周部加工フリーのハードディスク用ガラス基板を製造した。ホウケイ酸系ガラスは下記組成を有していた。SiO_２；64.0重量％、B_２O_３；5.5重量％、Al_２O_３；11.5重量％、Li_２O；5.4重量％、Na_２O；4.0重量％、K_２O；9.0重量％、CaO；0.5重量％、Ta_２O_５；0.1重量％。
【００５９】
【表２】

【００６０】
比較例2
アニール処理後、第1ラッピング処理前に、従来の外周粗加工処理を行ったこと、第1ラッピング処理後、第2ラッピング処理前に、順次、従来の端面精密加工処理および端面研磨加工処理を行ったこと以外、実施例2と同様の方法に従って、中央孔を備えていないハードディスク用ガラス基板を製造した。
従来の外周粗加工処理においては、ガラス基板の外周端部を切断してガラス基板の外径寸法および真円度を予備調整した。
従来の端面精密加工処理においては、外周端面を研削および面取りした。
従来の端面研磨加工処理においては、外周端面を研磨した。
【００６１】
実施例3
下記組成のマグネシウム・アルミノシリケート系ガラスを用いたこと以外、実施例1と同様の方法に従って、中央孔を備えた外周部加工フリーのハードディスク用ガラス基板を製造した。SiO_２；45.0重量％、Al_２O_３；18.0重量％、MgO；19.0重量％、TiO_２；10.0重量％、ZnO；1.5重量％、P_２O_５；1.5重量％、ZrO_２；3.0重量％、Nb₂O₅；2.0重量％。
【００６２】
得られたガラス基板を評価し、結果を以下に示した。
【表３】

【００６３】
実施例1および3で得られたガラス基板は中央孔を中心に回転させても、面ブレは起こらなかった。
実施例2で得られたガラス基板の重心に回転軸を連結させ、回転させても、面ブレは起こらなかった。
【００６４】
実施例および比較例で得られたガラス基板（それぞれ100枚）にNi-Alからなる下地層（膜厚100nm）、Co-Cr-Ptからなる記録層（膜厚20nm）、DLC：ダイヤモンドライクカーボンからなる保護層（膜厚5nm）を順次積層した。
全ての積層ガラス基板の外周端面を微分干渉顕微鏡によって倍率50倍で観察した。
実施例1〜3においては全てのガラス基板において積層が良好に行われていた。
比較例1においては、20枚のガラス基板において微小キズに起因する成膜不良が起こっていた。
比較例2においては、35枚のガラス基板において微小キズに起因する成膜不良が起こっていた。
【００６５】
【発明の効果】
本発明のハードディスク用ガラス基板は外周部加工フリーであるため、外周端面が十分に鏡面化されている。このため、当該ガラス基板表面（外周部端面を含む）に積層されている下地層、記録層および保護層等の侵食を長期にわたって防止できる。また本発明の外周部加工フリーのハードディスク用ガラス基板は重心を回転中心とされるため回転時において面ブレしない。さらに本発明の外周部加工フリーのハードディスク用ガラス基板はその製造工程において外周部の加工処理工程を省略できるため、簡便かつ低コストで製造可能である。
【図面の簡単な説明】
【図１】 本発明の外周部加工フリーのハードディスク用ガラス基板の製造方法の一例のフローチャートを示す。
【図２】 （A）は本発明の外周部加工フリーのハードディスク用ガラス基板の製造方法を説明するための上下型の概略構成図を示し、（B）は（A）の上下型を用いてプレスしたときの上型および下型の概略状態図を示す。
【図３】 （A）は本発明の外周部加工フリーのハードディスク用ガラス基板の製造方法の一例を説明するための上下型の概略構成図を示し、（B）は（A）の上下型を用いてプレスしたときの上型および下型の概略状態図を示す。
【図４】 従来のプレス成形方法を説明するための金型の概略構成図を示す。
【図５】 従来のプレス成形方法を説明するための金型の概略構成図を示す。
【図６】 従来のハードディスク用ガラス基板の製造方法のフローチャートを示す。
【符号の説明】
1；上型、2；下型、3；成形面、4；成形面、5；平行スペーサー、6；ガラス、15；外周端面、101；上型、102；下型、103；ガラス、105；上型、106；下型、107；リング状外径規制枠、108；ガラス。[0001]
BACKGROUND OF THE INVENTION
  The present inventionOf the glass substrate for hard disk whose outer periphery is not processedIt relates to a manufacturing method.
[0002]
[Prior art]
A hard disk used as an information recording medium of a computer is known as a type in which a base layer, a recording layer, and a protective layer are sequentially laminated on the surface of a glass disk-shaped substrate (including the outer peripheral end face). The disk-shaped substrate is used while being rotated about the center of rotation. In such a glass substrate, the outer peripheral portion is precisely processed. In particular, in a glass substrate for a hard disk having a central hole, the central hole is formed around the center of the glass substrate.
[0003]
A method for manufacturing a glass substrate for a hard disk will be briefly described with reference to the flowchart of FIG. First, a glass material is melted (glass melting step), the molten glass is poured onto a lower mold, and press molding is performed with the upper mold (press molding process). In the press molding process, generally, a method as shown in FIGS. 4 and 5 is adopted. In FIG. 4, the glass material 103 is simply press-molded to a predetermined thickness by the upper mold 101 and the lower mold 102 having a molding surface having a planar shape (Japanese Patent Laid-Open No. 11-255524). In FIG. 5, a glass material 108 is press-molded with a ring-shaped outer diameter regulating frame 107 interposed between an upper mold 105 and a lower mold 106 each having a molding surface having a planar shape. In detail, in the method shown in FIG. 5, the glass material 108 has its outer peripheral end surface in contact with the ring-shaped outer diameter regulating frame 107 during press molding, and the outer diameter of the glass substrate is regulated (Japanese Patent Laid-Open No. 7-133121). .
[0004]
The press-molded glass material (glass substrate) is crystallized or annealed and cooled (crystallization process or annealing process). The cooled glass substrate is perforated in the center if desired, and at least the outer peripheral edge of the glass substrate is cut to preliminarily adjust the outer diameter and roundness of the glass substrate (coring step or outer periphery). Roughing process). The glass substrate whose outer diameter is preliminarily adjusted is subjected to the first lapping process, both surfaces are ground, and the entire shape of the glass substrate, that is, the parallelism, flatness and thickness of the glass substrate are preliminarily adjusted ( First wrapping process). The glass substrate whose parallelism and the like are preliminarily adjusted is ground or chamfered at least on the outer peripheral end surface, and optionally on the inner peripheral end surface of the hole in the glass substrate, so that the outer diameter and roundness of the glass substrate and the inner diameter of the hole are measured. In addition, the concentricity between the glass substrate and the hole is finely adjusted (end face precision processing step (inside / outside)). The glass substrate whose outer diameter is finely adjusted, at least the outer peripheral end surface and, if desired, the inner peripheral end surface of the hole is polished to make the end surface mirror-finished (end surface polishing step (inside / outside)). The glass substrate whose end face has been polished is ground again on both surfaces, and the overall shape of the glass substrate, that is, the parallelism, flatness and thickness of the glass substrate are finely adjusted (second lapping step). The glass substrate whose degree of parallelism and the like is finely adjusted is subjected to a polishing process, both surfaces are polished, and the surface irregularities are leveled (polishing process). Polished glass substrates are finally cleaned and inspected, and only those that pass can be used as hard disk substrates.
[0005]
[Problems to be solved by the invention]
However, with the conventional method, the surface and the back surface of the glass substrate can be mirrored, but there is a limit to the mirroring of the outer peripheral end surface. That is, in the conventional method, the outer peripheral portion of the glass substrate is processed as described above, and particularly in the end surface polishing process, the processing of the end surface is complicated in spite of polishing the outer peripheral portion end surface of the glass substrate, and From the viewpoint of manufacturing cost, it is not possible to take much time to polish the end face, and thus the end face of the outer peripheral portion cannot be sufficiently mirror-finished. Specifically, fine scratches remained on the end face of the outer peripheral portion of the glass substrate obtained by the conventional method, and had a surface roughness of at least about 5 nm and a maximum surface roughness of about 250 nm. When minute scratches remain on the end face of the outer peripheral portion as described above, it is difficult to stack an underlayer, a recording layer, a protective layer, and the like on the scratch. In addition, even if an underlayer, a recording layer, a protective layer, and the like can be laminated on a minute scratch, the amount of alkali component that exudes from the minute scratch significantly increases as time passes. The underlying layer, the recording layer, the protective layer, and the like laminated on the edge surface (including the end face) were eroded from the outer periphery of the substrate relatively early, and as a result, the accumulated data was relatively easily destroyed. .
[0006]
This invention is made | formed in view of the said situation, Comprising: It aims at providing the glass substrate for hard disks by which the outer peripheral end surface was fully mirror-finished which can be manufactured simply and at low cost, and its manufacturing method. .
[0007]
[Means for Solving the Problems]
The present invention relates to a glass substrate for a hard disk that is free of processing of the outer peripheral portion.
[0008]
In the present invention, the glass is press-molded between the upper mold and the lower mold without regulating the end face of the outer peripheral portion of the glass, and after the crystallization process or the annealing process, the first lapping process and the second lapping process are performed. Further, the present invention relates to a method for manufacturing a glass substrate for a hard disk that is free of processing of the outer peripheral portion, characterized by performing a polishing process and a cleaning process.
[0009]
  The present invention also provides a glass forming process between the upper mold and the lower mold without restricting the end face of the outer periphery of the glass.To produce a glass substrate without a central holeThen, after the crystallization process or annealing process, the center of gravity of the glass substrate is detected, and the center of the center is formed by cutting the circular center part around the center of gravity, thereby forming a center hole around the center of gravity. And manufacturing a glass substrate for a hard disk that is free of outer periphery processing, characterized by performing a first lapping process, an inner peripheral end face precision processing process, an inner peripheral end face polishing process, a second lapping process, a polishing process, and a cleaning process. Regarding the method. The center of gravity is detected in the center of gravity coring process by performing image processing on a two-dimensional image from the thickness direction of the glass substrate.
[0010]
The inventors of the present invention are able to perform processing of a conventional glass substrate outer peripheral portion (outer peripheral end portion, outer peripheral end surface), that is, a coring step or outer peripheral rough processing step, an end surface precision processing step, and an end surface polishing processing step. Paying attention to the processing of the outer peripheral end and the outer peripheral end face, it has been found that the above object of the present invention can be achieved by omitting these processes and leaving the peripheral end face that is sufficiently mirror-finished unprocessed. The inventors of the present invention faced a new problem that the glass substrate obtained by omitting the above-described processing had a surface blurring during rotation because the outer peripheral portion was unprocessed. It has also been found that this can be solved by using the center of gravity of the glass substrate as the center of rotation.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
The glass substrate for hard disk of the present invention has an outer peripheral portion that is not processed, and has a free curved surface at the outer peripheral end face. In the glass substrate of the present invention, since the outer peripheral end face having a free-form surface is left unprocessed, the outer peripheral end face can have excellent mirror surface accuracy. That is, the free curved surface of the end face of the outer peripheral portion in the glass substrate of the present invention has a surface roughness (Ra) of 2.5 nm or less and a maximum surface roughness (Rmax) of 150 nm or less, and these values are preferably as small as possible. In the present invention, the free-form surface of the outer peripheral end face usually has a Ra of 0.1 to 2.5 nm, particularly 0.1 to 2.0 nm, and a Rmax of 1 to 150 nm, particularly 1 to 100 nm. If Ra exceeds 2.5 nm or Rmax exceeds 150 nm, the smoothness becomes insufficient, and there are minute scratches, and it is difficult to stack an underlayer, recording layer, protective layer, etc. on the scratches. Become. In addition, even if an underlayer, a recording layer, a protective layer, and the like can be laminated on the fine scratch, the amount of alkali component that exudes from the fine scratch increases remarkably over time. The underlying layer, the recording layer, the protective layer and the like laminated on the substrate are eroded from the outer periphery of the substrate relatively early, and the accumulated data is relatively easily destroyed.
[0012]
In this specification, the surface roughness (Ra) is an average value based on JIS B0601. The maximum surface roughness (Rmax) is the maximum value based on JIS B0601.
[0013]
The free curved surface having the mirror surface accuracy as described above may have a radius of curvature of about 1/2 with respect to the thickness of the glass substrate. The thickness of the glass substrate is usually preferably 0.2 to 2.5 mm.
[0014]
Since the glass substrate for hard disk of the present invention free of outer peripheral portion has almost no scratch on the end surface of the outer peripheral portion, the elution amount of alkali component can be effectively reduced. Alkaline component elution amount depends not only on the surface accuracy of the outer peripheral end surface, but also on the size of the glass substrate, the presence and size of the central hole, the ease of melting of the glass material (composition), etc. For example, outer diameter 65mm, thickness 0.635mm, front and back surface Ra0.5nm and Rmax5.0nm, central hole inner diameter 20mm, SiO₂; 69.0 wt%, Al₂O₃8.5% by weight, MgO; 2.0% by weight, TiO₂; 0.5 wt%, Li₂O: 7.0 wt%, ZnO: 7.0 wt%, P₂O₅; 2.5 wt%, ZrO₂The outer periphery processing free hard disk glass substrate of the present invention having a glass composition of 3.5% by weight is 0.21 μg / cm²Below, preferably 0.20μg / cm²The following alkaline component elution amount is achieved. A glass substrate similar to the above has an alkali elution amount of 0.22 μg / cm except that the outer peripheral end face is processed, Ra of the outer peripheral end face exceeds 2.5 nm, and Rmax exceeds 150 nm.²Thus, it becomes difficult to laminate a base layer or the like on the surface of the glass substrate (including the end face of the outer peripheral portion), or even if it can be laminated, the base layer or the like is eroded from the outer peripheral portion of the substrate relatively early.
[0015]
Also, for example, outer diameter 48mm, thickness 0.381mm, front and back surface Ra0.5nm and Rmax5.0nm, SiO₂; 64.0% by weight, B₂O₃; 5.5 wt%, Al₂O₃; 11.5 wt%, Li₂O: 5.4 wt%, Na₂O; 4.0% by weight, K₂O: 9.0 wt%, CaO: 0.5 wt%, Ta₂O₅The glass substrate for a hard disk having a glass composition of 0.1% by weight and having no central hole according to the present invention is 0.32 μg / cm²Or less, preferably 0.31 μg / cm²The following alkaline component elution amount is achieved. The glass substrate similar to the above, except that the outer peripheral end face is processed, Ra of the outer peripheral end face exceeds 2.5 nm, and Rmax exceeds 150 nm has an alkali elution amount of 0.33 μg / cm²Thus, it becomes difficult to laminate a base layer or the like on the surface of the glass substrate (including the end face of the outer peripheral portion), or even if it can be laminated, the base layer or the like is eroded from the outer peripheral portion of the substrate relatively early.
[0016]
Also, for example, outer diameter 95mm, thickness 1.270mm, front and back surface Ra0.5nm and Rmax5.0nm, central hole inner diameter 25mm, SiO₂; 45.0% by weight, Al₂O₃18.0% by weight, MgO; 19.0% by weight, TiO₂10.0 wt%, ZnO 1.5 wt%, P₂O₅; 1.5 wt%, ZrO₂; 3.0 wt%, Nb₂O_FiveThe outer peripheral portion processing-free glass substrate for hard disk of the present invention having a glass composition of 2.0% by weight hardly dissolves alkaline components.
[0017]
In this specification, the measurement of the elution amount of the alkali component was performed by the following method.
After immersing the glass substrate in 50 ml of reverse osmosis membrane water at 80 ° C. for 24 hours, the eluate was analyzed using an ICP emission analyzer (manufactured by Seiko Instruments Inc.), and the elution amount of alkali components per area of the substrate was calculated.
[0018]
The glass substrate for hard disk of the present invention free of outer peripheral portion processing has the center of gravity of the substrate as the center of rotation. The phrase “center of gravity as the center of rotation” means that the hard disk using the glass substrate for hard disk of the present invention is rotated around the center of gravity of the glass substrate. Specifically, when the glass substrate for hard disk of the present invention has a central hole, it means that the central hole is formed around the center of gravity of the substrate, and the glass substrate for hard disk of the present invention does not have a central hole. In this case, it means that the rotating shaft is connected to a position corresponding to the center of gravity of the substrate. In the present invention, as described above, the center of gravity of the outer peripheral portion processing-free glass substrate is set as the rotation center, so that even if the outer peripheral portion is unprocessed, surface blurring can be prevented.
[0019]
In this specification, the center of gravity means the center of gravity in the shape of the substrate when the glass substrate is viewed in a two-dimensional plane from the thickness direction, and a two-dimensional image from the thickness direction of the glass substrate is used with a laser beam system. It can be automatically detected by performing image processing with a non-contact optical shape measuring device (VIVID900: manufactured by Minolta Co., Ltd.).
[0020]
The outer diameter of the glass substrate of the present invention is not particularly limited, and is preferably 15 to 120 mm, for example. The outer diameter is determined depending on the amount of molten glass poured onto the lower mold in the manufacturing method described later and the distance (the thickness of the glass substrate) between the upper mold surface and the lower mold surface immediately before the press molding process is completed. The The outer diameter is expressed as an average value of the maximum outer diameter and the minimum outer diameter.
[0021]
The glass substrate of the present invention preferably has an E / ρ (E is Young's modulus (GPa) and ρ is specific gravity) of 27 to 52 from the viewpoint of preventing surface blurring and improving productivity, Preferably it is 29-50. E uses a value obtained by subjecting the obtained glass substrate for hard disk to a Young's modulus measuring device (manufactured by Kyoto Electronics Co., Ltd.), but it does not have to be measured by the above device and is the same as the above device. Any device can be used as long as it can be measured by the above principle. ρ is a value that can be easily calculated from the weight and volume of the obtained glass substrate for hard disk.
E is preferably 65 to 160 GPa.
ρ is preferably 2.2 to 3.3.
[0022]
The glass substrate of the present invention has an αs (αs is a linear thermal expansion coefficient in the range of 0 to 100 ° C.) of 40 × 10 0 from the viewpoint of effectively preventing surface blurring during use and cracking due to temperature change.^{- 7}~ 130 × 10^{- 7}/ ° C is preferred, more preferably 45 × 10^{- 7}~ 125 × 10^{- 7}/ ° C. αs uses a value obtained by subjecting the obtained glass substrate for hard disk to a thermal expansion measuring device (manufactured by Rigaku Corporation), but it does not have to be measured by the above device, and is the same as the above device. Any device that can measure by the principle may be used.
[0023]
Hereinafter, a method for producing a glass substrate for a hard disk free of outer periphery processing according to the present invention will be described in detail with reference to the flowchart of FIG. The flowchart of FIG. 1 shows a case where a glass substrate for a hard disk provided with a central hole is manufactured and a case where a glass substrate for a hard disk not provided with a central hole is manufactured. Specifically, when manufacturing a glass substrate for a hard disk having a central hole, the glass substrate obtained by melting and press-molding the glass is subjected to crystallization treatment or annealing treatment, and then sequentially subjected to gravity center coring treatment. The first lapping process, the inner peripheral end face precision processing process, the inner peripheral end face polishing process, the second lapping process, and the polishing process are performed. On the other hand, when manufacturing a glass substrate for a hard disk that does not have a central hole, the glass substrate obtained by melting and press-molding the glass is first crystallized or annealed, and then sequentially the first lapping process. Second wrapping process and polishing process. As described above, in the manufacturing method of the present invention, in the conventional glass substrate outer peripheral portion (outer peripheral end portion, outer peripheral end surface) processing (coring step or outer peripheral roughing step, end face precision processing step, and end surface polishing step) Since the processing of the outer peripheral end portion and the outer peripheral end surface of the glass substrate can be omitted, the manufacturing cost can be effectively reduced.
[0024]
In producing the glass substrate for hard disk of the present invention, first, a glass material is melted (glass melting step). The glass material used is not particularly limited. For example, an amorphous glass material such as lithium / aluminosilicate glass, magnesium / aluminosilicate glass or crystallized glass material, or borosilicate glass is used. The glass substrate to be obtained may be appropriately selected and used according to the desired form (crystallized glass or amorphous glass).
[0025]
As the lithium aluminosilicate glass, it is preferable to use a glass material having the following composition. SiO₂; 65 to 85% by weight, Al₂O₃3 to 15% by weight, MgO; 0 to 12% by weight, TiO₂; 0 to 10% by weight, Li₂O; 3 to 12% by weight, ZnO; 0 to 10% by weight, P₂O₅; 0-5% by weight, ZrO₂; 0 to 10% by weight. By using a glass material having such a composition, it is possible to easily reduce the alkaline component elution amount, particularly the alkaline component elution amount from the end face of the outer periphery, and erosion of the underlayer, recording layer, protective layer, etc. due to the alkaline component leaching. Can be more effectively prevented.
[0026]
As the magnesium-aluminosilicate glass, it is preferable to use a glass material having the following composition. SiO₂; 45-60% by weight, Al₂O₃12-25% by weight, MgO; 12-25% by weight, TiO₂; 0-12% by weight, Li₂O: 0 to 12% by weight, ZnO; 0 to 10% by weight, P₂O₅; 0-5% by weight, ZrO₂; 0 to 10% by weight, Nb₂O_Five; 0-5% by weight, Ta₂O_Five; 0-5% by weight, Y₂O_Three0-5% by weight. By using a glass material having such a composition, it is possible to easily reduce the alkaline component elution amount, particularly the alkaline component elution amount from the end face of the outer periphery, and erosion of the underlayer, recording layer, protective layer, etc. due to the alkaline component leaching. Can be more effectively prevented. Furthermore, a glass substrate having E / ρ within the above range can be easily obtained, and surface blurring and the like can be effectively prevented.
[0027]
As the borosilicate glass, it is preferable to use a glass material having the following composition. SiO₂; 50-69% by weight, B₂O₃; 0 to 15% by weight, Al₂O₃; 4-25% by weight, Li₂O; 2-7% by weight, Na₂O; 0 to 14% by weight, K₂O: 0 to 18% by weight, CaO; 0 to 6% by weight, Ta₂O₅0-3 wt%; BaO; 0-6 wt%; MgO; 0-6 wt%; SrO; 0-6 wt%; ZnO; 0-6 wt%. By using a glass material having such a composition, a glass substrate having αs in the above range can be easily obtained without performing crystallization treatment, and surface blurring and cracking can be effectively prevented.
[0028]
Next, the molten glass is poured from the nozzle onto the lower mold, and the glass is pressed between the upper mold and the lower mold without restricting the end surface of the outer periphery of the glass (press molding process). As long as the end surface of the glass outer peripheral portion is not regulated, that is, unless the end surface of the glass outer peripheral portion is in contact with any member, the press molding processing method is the same as the press molding processing method in the known method for manufacturing a hard disk glass substrate. The method can be adopted. For example, as shown in FIGS. 2 (A) and 2 (B), a glass material 6 is pressed to a predetermined thickness between upper and lower molds (1, 2) having a molding surface (3, 4) having a planar shape (pressing) Molding process). In this process, the outer peripheral end face 15 of the glass (see FIG. 2 (B)) is press-molded so that the outer peripheral end face of the resulting glass substrate has a free-form curved surface with excellent specular accuracy. Achieve.
[0029]
Generally, the press pressure is 20-100kg / cm²The pressing time is suitably from 0.3 to 2.0 seconds.
[0030]
After the press molding process, the glass substrate is usually crystallized or annealed and cooled as a result (a crystallization process or an annealing process). Whether to perform crystallization treatment or annealing treatment depends on the desired form (crystallized glass or amorphous glass) of the glass substrate to be obtained. When an amorphous glass is used as a substrate, an annealing process is performed to remove internal strain.
[0031]
As the crystallization treatment and annealing treatment methods, methods similar to the crystallization treatment and annealing treatment methods in the known methods for producing hard disk glass substrates can be employed. For example, in a crystallization process, a glass substrate is usually heated to a glass transition point (Tg) + 50 ° C. to Tg + 300 ° C. of the glass material, and then kept at a constant temperature or controlled while controlling the temperature (Tg ) Cooling to near, then gradually cooling, but by properly selecting the heating temperature, holding time, cooling rate to Tg, etc., the physical properties of the glass substrate, such as thermal expansion coefficient (linear thermal expansion coefficient), Young The rate, crystallinity, etc. can be controlled. In the annealing treatment, usually, after holding for a certain time in the vicinity of Tg of glass, the strain point is cooled at a relatively low cooling rate, and thereafter, it is cooled at a relatively high cooling rate. In the present invention, in crystallization treatment or annealing treatment, particularly crystallization treatment, a plurality of glass substrates are stacked from the viewpoint of saving space in the processing apparatus and improving the flatness of the glass substrate for hard disk, and weighting is performed thereon. It is preferable to apply the pressure by the treatment. At this time, it is preferable that the glass substrate is processed by being alternately stacked with the setter material from the viewpoint of preventing fusion between the substrates. Flatness is one index that represents the degree of warpage of the glass substrate.
[0032]
Subsequently, the glass substrate cooled in the crystallization process or the annealing process is sequentially subjected to the center-of-gravity coring process and the first lapping process (when manufacturing a glass substrate for a hard disk having a central hole) or the center of gravity. The first lapping process is performed without performing the coring process (when manufacturing a glass substrate for a hard disk that does not have a central hole).
[0033]
In the center-of-gravity coring process performed when manufacturing a glass substrate for a hard disk having a center hole, the center hole is formed around the center of gravity of the glass substrate. Specifically, a two-dimensional image of the substrate from the thickness direction of the glass substrate is image-processed by a non-contact optical shape measuring apparatus using a laser beam method to detect the center of gravity, and a circular shape centered on the center of gravity is detected. Cut the center. As the cutting method, a method similar to the cutting method for forming the center hole in the known method for producing a glass substrate for hard disk can be employed. For example, a method for precision machining of the inner periphery, a desired cutting area on at least one surface of the glass substrate is marked with a diamond cutter, etc. And a method of cutting by cutting the outline of a desired cutting region in the glass substrate with a laser beam. In the present invention, since the center-of-gravity coring process is performed as described above, it is possible to prevent surface blurring in the outer peripheral portion processing-free glass substrate having the central hole.
[0034]
Next, a first wrapping process is performed on the glass substrate that has been subjected to the center-of-gravity coring process (first lapping process) (when manufacturing a glass substrate for a hard disk having a central hole). When manufacturing a glass substrate for a hard disk that does not have a central hole, the first lapping process is performed on the glass substrate cooled in the crystallization process or the annealing process. The same is true for the first lapping process in any of the above cases, and in this process, the parallelism, flatness and thickness of the glass substrate are preliminarily adjusted by grinding both surfaces of the glass substrate. Here, the preliminary adjustment refers to a rough adjustment to such a degree that a dimension or the like can be adjusted to a prescribed dimension or the like in another subsequent process.
[0035]
In this specification, the parallelism is generated when one of the upper mold center axis and the lower mold center axis is inclined with respect to the other axis. This is one index representing the degree of “inclination with the surface (lower surface) onto which the mold forming surface is transferred”. In the present invention, the inclination between the upper surface and the lower surface is “the inclination of the upper surface when the lower surface is regarded as a horizontal surface”, and the parallelism is the difference in height due to the inclination of the upper surface per 100 mm length of the lower surface in the cross section where the inclination is the largest. expressed. In the present invention, such parallelism uses a value measured by a digimatic indicator (manufactured by Mitutoyo Corporation), but it does not have to be measured by the above-mentioned apparatus, and an apparatus capable of measuring the above-described parallelism. Any apparatus may be used for measurement.
[0036]
The flatness is an index indicating the degree of warpage of the molded product, and is expressed by the distance between the highest point on the upper surface when the molded product is placed on the horizontal plane and the horizontal plane. In the present invention, such flatness uses a value measured by a digimatic indicator (manufactured by Mitutoyo Corporation). However, the flatness is not necessarily measured by the above-mentioned device, and an apparatus capable of measuring the above-described flatness. Any apparatus may be used for measurement.
[0037]
In the present invention, the thickness is a value measured by a digital micrometer (manufactured by Mitutoyo Corporation), but may be measured by any apparatus.
[0038]
As the method of the first lapping treatment, a method similar to the method of the first lapping treatment in the known method for producing a glass substrate for hard disk can be employed. Specifically, grinding is performed using an abrasive such as fixed abrasive grains (diamond pellets) or loose abrasive grains (alumina, SiC slurry, etc.) having a grain size of # 600 or more and # 2000 or less, preferably # 800 or more and # 2000 or less. .
As the wrapping device used in the first wrapping step, a known wrapping device can be used, and examples thereof include a double-sided wrapping device (made by Hamai Co.) and a double-sided wrapping device (made by Speed Fem Co.).
[0039]
Next, whether or not the first lapping-treated glass substrate is sequentially subjected to inner peripheral end surface processing (inner peripheral end surface precision processing and inner peripheral end surface polishing processing) and second lapping processing (hard disk having a central hole) The second lapping process is performed without performing the inner peripheral end face process (when manufacturing a glass substrate for a hard disk without a central hole).
[0040]
In the inner peripheral end face precision processing performed when manufacturing a glass substrate for hard disk with a central hole, only the inner peripheral end face of the central hole in the glass substrate is ground without processing the outer peripheral end face of the glass substrate. Then, the inner diameter dimension of the central hole and the concentricity between the glass substrate and the hole are finely adjusted to a prescribed dimension and degree.
The inner peripheral end face precision processing method adopts the same method as the end face precision processing method in the known method for manufacturing a glass substrate for hard disk, except that the surface to be processed is limited to the inner peripheral end face of the hole. can do. For example, the inner peripheral end face of the hole is ground or chamfered using fixed abrasive grains (diamond pellets), loose abrasive grains (alumina, slurry such as SiC), and the like as the abrasive.
[0041]
In the inner peripheral end surface polishing processing, only the inner peripheral end surface of the central hole in the glass substrate is polished to remove minute scratches without processing the outer peripheral end surface of the glass substrate. The reason why the outer peripheral end surface of the glass substrate is not processed is that the glass substrate already has a free curved surface with excellent mirror surface accuracy at the outer peripheral end surface. If the inner peripheral end face has a minute scratch, the glass substrate is easily damaged by impact. The hard disk substrate is about 1 mm from the inner peripheral end surface to the laminated recording layer, and erosion of the base layer, recording layer, protective layer, etc. due to leaching of alkali components from the inner peripheral end surface is not a problem with the current Ra and Rmax Absent. For this reason, in the present invention, the possibility of accumulated data destruction due to erosion of the underlayer, the recording layer, the protective layer, etc. can be remarkably reduced simply by making the outer peripheral portion processing free and effectively reducing minute scratches on the outer peripheral end face. . Therefore, in this process, the minute scratches on the inner peripheral end surface may be removed to such an extent that the glass substrate is not easily damaged by impact.
[0042]
Such an inner peripheral end surface polishing method is the same as the end surface polishing method in a known method for manufacturing a hard disk glass substrate, except that the surface to be processed is limited to the inner peripheral end surface of the hole. The method can be adopted. For example, the inner peripheral end face of the hole is polished using cerium oxide as an abrasive.
[0043]
Next, a second lapping process is performed on the glass substrate that has been subjected to the inner peripheral end surface polishing process (second lapping process) (when a glass substrate for a hard disk having a central hole is manufactured). In the case of manufacturing a glass substrate for hard disk that does not have a central hole, a second lapping process is performed on the glass substrate that has been subjected to the first lapping process. The same applies to the second lapping process in any of the above cases. In this process, both surfaces of the glass substrate are ground to create (correct) the surface shape accuracy (second lapping process). That is, the shape quality (parallelism, flatness and thickness) of the final disk is achieved, and at the same time, the surface roughness and the maximum surface roughness that can be adjusted by the polishing process described later are achieved.
[0044]
As the second lapping treatment method, a method similar to the second lapping treatment method in a known method for producing a glass substrate for hard disk can be employed. Specifically, grinding is performed using an abrasive such as fixed abrasive grains (diamond pellets) or loose abrasive grains (alumina, SiC, etc.) having a grain size of # 1000 or more, # 2000 or less, preferably # 1200 or more and # 2000 or less. .
Examples of the wrapping device used in the second wrapping step include the same devices as those exemplified as the wrapping device used in the first wrapping step.
[0045]
Next, the lapped glass substrate is polished to create (adjust) the smoothness of the surface (Polishing step). That is, the unevenness of the surface is leveled to achieve smoothness (surface roughness, maximum surface roughness) as a final disk.
[0046]
As the polishing method, a method similar to the polishing method in a known method for producing a glass substrate for hard disk can be employed. Specifically, polishing is performed using an abrasive such as cerium oxide having an average primary particle size of 2 μm or less, preferably 1 μm or less, and the surface roughness (Ra) is 1 nm or less, preferably 0.5 nm or less, and the maximum surface roughness (Rmax) is 20 nm. Hereinafter, preferably 10 nm or less is achieved. Thus, the front and back surfaces of the glass substrate can achieve excellent mirror surface accuracy relatively easily, so that erosion of the underlayer, the recording layer, the protective layer, and the like derived from minute scratches on the front and back surfaces can be relatively easily prevented. . As the polishing apparatus, for example, a double-sided polishing board (made by Hamai Co.) is used.
[0047]
Finally, the polished glass substrate is generally cleaned and inspected (cleaning process and inspection process).
In the cleaning step, glass waste on the substrate surface may be removed by exposing the glass substrate to running water at room temperature.
In the inspection process, the parallelism, flatness, thickness, surface roughness, maximum surface roughness, concentricity, roundness, end shape (roll-off), minute undulation, etc. of the substrate are within the desired range. Is confirmed and used as a substrate for hard disks.
[0048]
In another aspect of the manufacturing method of the outer peripheral portion processing-free hard disk glass substrate of the present invention, in the press molding process, a parallel spacer is interposed between the upper die and the lower die, and the outer peripheral portion of the glass It is preferable to press the glass between the upper die and the lower die while maintaining the non-contact state with the parallel spacer. The parallel spacer has a function of holding the upper mold surface and the lower mold surface in parallel immediately before the press molding is completed. By performing such a press molding treatment, the accuracy of the parallelism, flatness and thickness variation of the obtained glass substrate is improved. For this reason, the first lapping process performed mainly for the purpose of preliminarily adjusting the parallelism, flatness, and thickness can be omitted. Further, even if the first lapping process is performed, the processing time can be shortened and the manufacturing cost can be reduced.
[0049]
Specifically, for example, as shown in FIGS. 3 (A) and (B), when the glass is pressed by moving the upper mold 1 and the lower mold 2 closer, the approach movement is limited by the parallel spacer 5, and the molten glass 6 Is defined (see FIG. 3B). At this time, the parallel spacer 5 is installed at the outer edge of the molding surface so that the outer periphery of the glass and the parallel spacer can be kept in a non-contact state during press molding (see FIG. 3 (B)). Since the outer peripheral portion of the glass does not come into contact with the parallel spacer 5, it is possible to achieve excellent accuracy in terms of parallelism, flatness, and thickness variation. Further, the mold forming surface can be effectively transferred to the glass substrate surface. FIG. 3A shows a schematic cross-sectional view of an upper die and a lower die provided with parallel spacers, a schematic sketch when the upper die is viewed from below, and a schematic sketch when the lower die is viewed from above. FIG. 3B shows a schematic state diagram of the upper die and the lower die when pressed using the upper die and the lower die of FIG.
[0050]
In this aspect, in order to achieve improvement in accuracy in terms of parallelism, flatness, and thickness variation, the contact surface of the parallel spacer with the upper mold and the lower mold, the contact surface of the upper mold and the lower mold with the parallel spacer, and the upper The molding surfaces of the mold and the lower mold preferably have a parallelism of 10 μm or less, preferably 5 μm or less, and a flatness of 10 μm or less, preferably 5 μm or less.
[0051]
In FIG. 3 (A), the parallel spacer 5 is installed on the upper mold 1, but it may be installed on the lower mold 2. When the parallel spacer 5 is installed in the upper mold 1, when a plurality of continuous molding is performed using a turntable having a plurality of lower molds with respect to the upper mold 1, it is only necessary to prepare the minimum number of parallel spacers. In addition, the molded product on the lower mold can be easily taken out after completion of the molding.
[0052]
In FIG. 3 (A), the parallel spacer 5 has a prismatic shape and is in surface contact with the lower mold forming surface 4, but the shape is not particularly limited as long as the molding surfaces of both molds can be kept parallel. The shape may be a substantially cylindrical shape, a substantially pyramid shape, a substantially cone shape, a substantially rod shape, a substantially pin shape, or the like. Depending on the shape, the parallel spacer contacts the molding surface 4 at a point, line or surface. From the viewpoint of obtaining a molded article having excellent accuracy such as parallelism, flatness, and thickness over a long period of time, it is preferable to use a parallel spacer that makes contact with the lower mold molding surface. As long as the glass and the parallel spacer do not contact at the time of press molding, the parallel spacer 5 may have a ring shape.
[0053]
Also, in FIG. 3 (A), four parallel spacers 5 are used, but the number of parallel spacers is not particularly limited as long as the molding surfaces of both molds can be kept parallel, and is in surface contact or line contact with the lower mold molding surface. In some cases, at least 2, preferably 3, and in case of point contact with the lower mold surface, at least 3, preferably 3, are suitable.
[0054]
Since the thickness (height) of the parallel spacers 5 reflects the thickness and parallelism of the glass substrate, it is necessary that the thicknesses (heights) of all the parallel spacers used be strictly equal.
[0055]
【Example】
Based on the flowchart shown in FIG. 1, a glass substrate was manufactured under the conditions shown in the following table.
Example 1
Based on the flowchart of FIG. 1, an outer peripheral portion processing-free glass substrate for a hard disk having a central hole was manufactured. The lithium aluminosilicate glass had the following composition. SiO₂; 69.0 wt%, Al₂O₃8.5% by weight, MgO; 2.0% by weight, TiO₂; 0.5 wt%, Li₂O: 7.0 wt%, ZnO: 7.0 wt%, P₂O₅; 2.5 wt%, ZrO₂; 3.5% by weight.
[0056]
[Table 1]

[0057]
Comparative Example 1
Conventional coring process instead of center of gravity coring process, conventional end face precision machining process (internal and external) instead of inner peripheral end face precision machining process, conventional end face polishing process instead of inner peripheral end face polishing process ( A glass substrate for a hard disk provided with a central hole was produced in the same manner as in Example 1 except that the inside and outside were performed.
In the conventional coring process, the outer peripheral edge of the glass substrate is cut to preliminarily adjust the outer diameter and roundness of the glass substrate, and then a central hole is formed around the center of the glass substrate.
In the conventional end face precision processing (inside and outside), the outer peripheral end face was ground and chamfered together with the inner peripheral end face of the central hole.
In the conventional end face polishing processing (inside and outside), the outer peripheral end face was polished together with the inner peripheral end face of the central hole.
[0058]
Example 2
Based on the flowchart of FIG. 1, a glass substrate for a hard disk free of outer peripheral portion processing without a central hole was manufactured. The borosilicate glass had the following composition. SiO₂; 64.0% by weight, B₂O₃; 5.5 wt%, Al₂O₃; 11.5 wt%, Li₂O: 5.4 wt%, Na₂O; 4.0% by weight, K₂O: 9.0 wt%, CaO: 0.5 wt%, Ta₂O₅; 0.1% by weight.
[0059]
[Table 2]

[0060]
Comparative Example 2
After the annealing process and before the first lapping process, the conventional outer peripheral roughing process was performed, and after the first lapping process and before the second lapping process, the conventional end face precision processing process and end face polishing process process were sequentially performed. A glass substrate for a hard disk not having a central hole was produced in the same manner as in Example 2 except that.
In the conventional outer periphery roughing process, the outer peripheral end portion of the glass substrate was cut to preliminarily adjust the outer diameter and roundness of the glass substrate.
In the conventional end face precision processing, the outer peripheral end face was ground and chamfered.
In the conventional end surface polishing processing, the outer peripheral end surface was polished.
[0061]
Example 3
According to the same method as in Example 1 except that a magnesium / aluminosilicate glass having the following composition was used, an outer peripheral portion processing-free glass substrate for a hard disk having a central hole was produced. SiO₂; 45.0% by weight, Al₂O₃18.0% by weight, MgO; 19.0% by weight, TiO₂10.0 wt%, ZnO 1.5 wt%, P₂O₅; 1.5 wt%, ZrO₂; 3.0 wt%, Nb₂O_Five2.0% by weight.
[0062]
The obtained glass substrate was evaluated, and the results are shown below.
[Table 3]

[0063]
Even when the glass substrates obtained in Examples 1 and 3 were rotated around the central hole, no surface blur occurred.
Even when a rotating shaft was connected to the center of gravity of the glass substrate obtained in Example 2 and rotated, surface blurring did not occur.
[0064]
The glass substrate (100 sheets each) obtained in the examples and comparative examples, Ni—Al base layer (film thickness 100 nm), Co—Cr—Pt recording layer (film thickness 20 nm), DLC: diamond-like carbon A protective layer (film thickness: 5 nm) made of was sequentially laminated.
The outer peripheral end faces of all the laminated glass substrates were observed with a differential interference microscope at a magnification of 50 times.
In Examples 1 to 3, the lamination was satisfactorily performed on all the glass substrates.
In Comparative Example 1, there was a film formation defect due to minute scratches on 20 glass substrates.
In Comparative Example 2, there was a film formation defect due to minute scratches on 35 glass substrates.
[0065]
【The invention's effect】
Since the glass substrate for hard disk of the present invention is free from processing of the outer peripheral portion, the outer peripheral end surface is sufficiently mirror-finished. For this reason, erosion of the underlayer, the recording layer, the protective layer, and the like laminated on the surface of the glass substrate (including the outer peripheral end face) can be prevented over a long period of time. In addition, since the glass substrate for hard disk of the present invention which is free of processing of the outer peripheral portion has the center of gravity as the center of rotation, it does not run out during rotation. Furthermore, since the outer peripheral portion processing-free glass substrate for hard disk of the present invention can omit the outer peripheral portion processing step in the manufacturing process, it can be manufactured easily and at low cost.
[Brief description of the drawings]
FIG. 1 shows a flowchart of an example of a method for manufacturing a glass substrate for a hard disk free of outer periphery processing according to the present invention.
FIG. 2A is a schematic configuration diagram of an upper and lower mold for explaining a method for manufacturing a glass substrate for a hard disk according to the present invention, and FIG. A schematic state diagram of the upper die and the lower die when pressed is shown.
FIG. 3A is a schematic configuration diagram of an upper and lower mold for explaining an example of a manufacturing method of a glass substrate for a hard disk of the outer periphery processing according to the present invention, and FIG. The schematic diagram of the upper die and the lower die when used and pressed is shown.
FIG. 4 is a schematic configuration diagram of a mold for explaining a conventional press molding method.
FIG. 5 is a schematic configuration diagram of a mold for explaining a conventional press molding method.
FIG. 6 shows a flowchart of a conventional method for manufacturing a glass substrate for hard disk.
[Explanation of symbols]
1; Upper die, 2; Lower die, 3; Molding surface, 4; Molding surface, 5; Parallel spacer, 6; Glass, 15; Peripheral end surface, 101; Upper die, 102; Lower die, 103; Upper mold, 106; lower mold, 107; ring-shaped outer diameter regulating frame, 108; glass.

Claims (2)

Without restricting the end face of the glass outer peripheral part, by pressing the glass between the upper mold and the lower mold to produce a glass substrate without a central hole, after crystallization treatment or annealing treatment, The center of gravity of the glass substrate is detected, and the center of the circular shape centered on the center of gravity is cut to perform center of gravity coring that forms a center hole around the center of gravity. A method of manufacturing a glass substrate for a hard disk that is free of outer peripheral portion processing, characterized by performing processing processing, inner peripheral end surface polishing processing, second lapping processing, polishing processing, and cleaning processing.   The center-of-gravity detection in the center-of-gravity coring process is performed by performing image processing on a two-dimensional image from the thickness direction of the glass substrate. Production method.

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